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Considerations for Exposure to Diazinon and Chlorpyrifos Clement E. Furlong, PhD Research Professor Departments of Medicine (Div. Medical Genetics), and Genome Sciences University of Washington, Seattle, WA 98195-7720 [email protected] Goals of This Presentation The purpose of this brief presentation is to share with you what we have learned about human genetic variability in paraoxonase 1 (PON1) and the consequences of this variability with respect to gene/environment interactions, specifically the role of PON1 in protecting against exposure to organophosphorus insecticides, particularly diazinon/diazoxon and chlorpyrifos/chlorpyrifos oxon. PON1 is a high density lipoprotein (HDL) associated enzyme of 354 amino acids that plays a significant role in the hydrolysis of the highly toxic diazinon metabolite diazoxon. (Also the toxic metabolite of chlorpyrifos, chlorpyrifos oxon). The presentation also describes the results of experiments carried out in a mouse model. These experiments were designed to provide information on the physiological consequences of the PON1 genetic variability in human populations. Detoxicaton of OP Insecticides The commonly used organophosphorus insecticides parathion, chlorpyrifos and diazinon are manufactured as organoposphorothioates. These compounds are very poor inhibitors of cholinesterases. In organisms (target and non-target) the thioate is converted to an oxon form by cytochromes P450. Also, as discussed below, actual exposures include both parent thioate residues as well as the highly toxic oxon forms. It was thought that mammals could detoxify the oxons as rapidly as they were formed. However, in recent years, it has become apparent that there is considerable variability in different individuals’ plasma paraoxonase (PON1) levels that are controlled developmentally and genetically. The following slides will elaborate on these factors and the consequence of high vs. low plasma PON1 levels. An additional concern based on recent findings of researchers from North Carolina State University is that the thioates are suicide substrates for the P45O enzymes that catalyze the oxidative desulfuration of the parent compounds. Of particular interest is the inactivation of cytochromes P450 3A4 and 1A2 that are important in the metabolism of testosterone and estradiol. Cytochrome P450-Paraoxonase (PON) pathway for Organophosphate Detoxification R>>Q O S (O) NO2 (EtO)2PO (H2O) (EtO)2PO microsomal oxidation Parathion NO2 plasma paraoxonase Paraoxon NO2 HO + p-Nitrophenol R>>Q Cl Cl Cl (O) S (EtO)2PO Cl N Chlorpyrifos microsomal (EtO)2PO oxidation (EtO)2PO N R=Q Diazinon N N (EtO)2PO2- + Cl 3,5,6-Trichloro-2pyridinol plasma paraoxonase HO HC(CH3)2 Diazoxon + N N (EtO)2PO2- HC(CH3)2 Diethyl Phosphate IMHP Q>>>R O H O F CH3 H CH3 CH3 P CH3 Soman Davies et al., Nature Genetics 1996 P OH F - + CH3 Q>R (H2O) O O O CH3 Sarin CH3 CH3 CH3 CH3 Nerve agents P O H (H2O) CH3 Diethyl phosphate CH3 (H2O) O microsomal oxidation (EtO)2PO HC(CH3)2 Diethyl phosphate Cl Cl plasma HO paraoxonase Cl N CH3 (O) N (H2O) Chlorpyrifos oxon CH3 S Cl O (EtO)2PO2- F CH3 O H O CH3 CH3 CH3 P CH3 OH + F - Problems with Safety Tests • Most if not all safety tests were carried out with highly pure parent compounds (usuallly >99%). • Exposures may contain a significant percentage of highly toxic oxon form of the OP. • The oxon form is a much more potent inhibitor of cholinesterase than parent compound • The genetic and developmental variability of sensitivity to the oxon component is significant • Thioates are suicide substrates for P450s Concerns about Product Safety Tests One of the important factors to consider is how the safety tests were carried out with respect to what we now know about the genetically and developmentally variable sensitivity to diazinon/diazoxon exposures. Safety tests were carried out with highly pure parent compounds, which at the time were the types of tests required by regulatory agencies. Examples of Purity of Parent Compounds Used for Safety Tests Safety studies with diazinon used parent compound of 99.5% purity.. For details see: The reconsideration of approvals of the active constituent diazinon, registrations of products containing diazinon and approval of their associated labels. Part 2 Preliminary Review Findings Volume 2 of 2 Technical Reports, June 2006. Australian Pesticides & Veterinary Medicines Authority. Canberra Australia Safety studies with chlorpyrifos oxon used parent compound of very high purity. Nolan RJ, Rick DL, Freshour NL, Saunders JH. (1984) Chlorpyrifos: pharmacokinetics in human volunteers. Toxicol Appl Pharmacol; 73: 8–15. Literature Survey of Oxon Values in Leaf Foliar Residues Table 1 Oxon levels in total pesticide residues taken from dislodgeable leaf foliar residue and dermal exposure studies Pesticide (units) Ralls et al. (1966) Diazinon (ppmd) Kansoug and Hopkins (1968) Diazinonb Wolfe et al. (1975) Parathion (ng/cm2)d Kraus et al. (1977) Azinphosmethyl (%)d Nigg et al. (1977) Ethion (ng/cm2)d Spear et al. (1977a) Parathion (ng/cm2)d Parathion (mg)e Spear et al. (1977b) Parathion (ng/cm2)d Maddy and Meinders (1987) Azinphosmethyl (mg)e Costello et al. (1989) Malathion (mg)e Schneider et al. (1990) Azinphosmethyl (ng/cm2)d Azinphosmethyl (mg)e Spencer et al. (1991) Azinphosmethyl (%)d McCurdy et al. (1994) Azinphosmethylb Oxona 0.05 NDc 8 0.05 42 84 145 229 ND 659 0.008 272 15 - Thioate 0.25 106 99.95 285 29 39 8 2301 0.31 1450 85 - Total OP 0.3 114 100 327 113 184 237 2960 0.32 1722 100 - Oxon (%) 17 ND 7 0.05 13 74 79 97 ND 22 2.5 16 15 2.3 a Based on the highest value reported in study. Units or values not given in study. c ND, none detected. d Foliar residue measurement. e Dermal monitoring measurement. b Yuknavage et al., J. Toxicol. Environ. Health 1997; 51:35-55 Oxon Residues in Exposures Real-life exposures, contain variable levels of highly toxic oxon components. In the study by Ralls et al., the oxon content of the diazinon residues represented 17% of the total residue. In light of what is now known, it makes sense for safety tests to include a range of oxon contents that include percentages of oxon likely to be encountered in actual exposures. [Ralls, J. W., Gilmore, D. R., and Cortes, A. 1966. Fate of radioactive O,O-diethyl O(2-iso-propyl-4-methylpyridmidin-6-yl) phosphorothioate on field-grown experimental crops. J. Agric. Food Chem. 14:387–392.] Inhibition of ChE By CPS/CPO Chlorpyrifos oxon (CPO, the toxic metabolite of chlorpyrifos) inhibits brain cholinesterase at approximately 1000-times the rate of chlorpyrifos (CPS). This is an important observation in light of the importance of the PON1 polymorphism in detoxifying parent organophosphorothioates (e.g., chlorpyrifos and diazinon) and the oxon contents of residues. Huff et al. J Pharmacol Exp Therapeutics 269:329-335(1994) Some Concerns About the Parent Organophosphorothioates For many years, it was thought that the parent organophosphorothioates were quite safe compounds, i.e. they are very poor inhibitors of cholinesterases. However, recent studies reported by Usamani and colleagues at Duke University (see next slide) noted that cytochrome P450 3A4 was inhibited during the bioactivation of parent organophosphorothioate compounds. Since this P450 is an important enzyme in testosterone metabolism, this raises a number of concerns about exposures to the parent compound, particularly questions about consequences of exposure during critical windows of development and affects on reproductive health. Concerns about the parent thioates “Preincubation of CYP3A4 with chlorpyrifos, but not chlorpyrifos-oxon, resulted in 98% inhibition of TST metabolism.” Gene Frequency of PON1 Activity Polymorphism Early studies of the genetic variability of serum paraoxonase (PON1) activities in different ethnic groups. Note in the next slide the different allele frequencies of the PON1 activity polymorphism in different populations. In populations of Northern European origin, approximately one-half of the populations were low metabolizers. Other populations of African or Asian origin had very few low metabolizers (For an excellent review of the early PON1 studies, see Geldmacher v.-Mallinckrodt and Diepgen, Toxicol and Environ Chem 1988; 18:79-196). Examples of the Polymorphic Distribution of PON1 Activity in Different Populations See below that this analysis will not resolve 3 phenotypes accurately T.L. Diepgen & M. Geldmacher-v. Mallinckrodt. Arch. Toxicol. Suppl. 9, 154-158 (1986) DNA Analysis of the PON1-192 Polymorphism A DNA segment that includes the polymorphic site that specified which amino acid appears at position 192 is amplified by enzymes in a process referred to as a polymerase chain reaction (PCR). A method that has come to public attention through highly visible criminal trials. The resulting fragments of DNA are exposed to a specific restriction enzyme that will cut DNA containing the codon for Q, but not for R. The fragments are separated by an electrophoretic procedure, then stained and photographed. In the next slide, the uncut polymerase chain reaction (PCR) product runs at the position of the upper arrow, while the cut sequence runs at the position of the lower arrow. The genotypes of the individuals are shown above their respective band patterns. X = no DNA in the amplification reaction. Q = DNA from a Q/Q homozygote, R from an R/R homozygote. The PON1-R192 allele was shown to be the high paraoxonase activity allele and the PON1-Q192 allele the low metabolizer allele. As noted below, we recommend not using this protocol, but instead, a functional analysis that provides additional information on PON1 levels which are as important or more important than the amino acid present at position 192. PCR Analysis of PON1192 Genotype Q/R R/R Q/Q X Humbert et al. Nature Genet 3:73-76 QR PON1 Status Recently, much better functional two-substrate assays have been developed that separate populations into individuals with specific functional genotypes as will be described below. The assay also provides the level of enzyme present in the plasma of each individual. An important genetic variability in the amino acid present at position 192 of this 355 amino acid protein [glutamine (Q) or arginine (R)] determines whether the PON1 in an individual can hydrolyze paraoxon rapidly or slowly. Since the two so-called alloforms of paraoxonase (PON1-Q192 or PON1-R192) have different properties, this analysis provides the resolution of phenotypes shown in the slide. In the data shown in this slide, DNA analysis was also carried out. There were some discrepancies observed, where the DNA sequence was observed to specify a heterozygous genotype at position 192 (Q/R) where as the functional assay showed that only one alloform was present in the individual’s plasma. Further studies involving sequencing the entire PON1 genes of these individuals elucidated the reason for the discrepancy. These individuals had PON1 genes that were defective at regions of the gene away from that analyzed by the DNA analysis protocol as noted in the slide. These observations serve to illustrate the accuracy of the functional 2-substrate assay. [Richter, RJ and Furlong, CE. 1999. Determination of paraoxonase (PON1) status requires more than genotyping. Pharmacogenetics 9:745-753; Jarvik GP, R Jampsa, RJ Richter, C Carlson, M Rieder, D Nickerson and CE Furlong. 2003. Novel Paraoxonase (PON1) nonsense and missense mutations predicted by functional genomic assay of PON1 status. Pharmacogenetics 13:291-295.] Determination of PON1 Status What are the consequences of this genetic variability? Newly discovered PON1 SNPs resolve anomalous individuals in the correlation of enzyme activities and PON1 Q192R genotypes Jarvik et al. 2003. Pharmacogenetics 13:291-295 Why are young individuals more sensitive to OP compounds? Developmental regulation of plasma PON1 levels is such that newborns have only 1/4th to 1/3rd the levels of plasma PON1 compared with adults. [Cole TB, RL Jampsa, BJ Walter, TL Arndt, RJ Richter, DM Shih, A Tward, AJ Lusis, RM Jack, LG Costa, and CE Furlong. 2003. Expression of human paraoxonase (PON1) during development. Pharmacogenetics 13:357-364 and references cited therein.] What are the consequences of high PON1 levels? Early studies on the effects of high PON1 levels on resistance to OP exposure involved the injection of purified rabbit PON1 into mice and challenging the mice with a dermal exposure to OPs. The early studies were mostly carried out with chlorpyrifos oxon or chlorpyrifos. To test whether PON1 protects against OP exposure, we first determined the most suitable route of administration of purified rabbit PON1 into mice. Injection via the iv route was chosen for the experiment on the next slide. At time zero, purified rabbit PON1 was injected into mice via the tail vein and rates of PON1 hydrolysis of chlorpyrifos oxon (CPOase) and paraoxon (POase) were monitored over time. (Li et al., J Toxicol and Environ Health 1993; 40:337-346). Plasma levels of PON1 can be increased by injecting purified rabbit PON1 Enzyme Activity (Units/Liter) 80000 iv Injection 8000 60000 6000 40000 4000 20000 2000 CPOase POase 0 0 0 5 10 15 20 Time (Hours) 25 30 Injected PON1 Protects Against OP Exposure The next slide shows the results of dermal exposure to chlorpyrifos oxon (CPO, 14 mg/kg) of mice injected with purified rabbit PON1 compared with mice not receiving purified rabbit PON1. It is clear from the slide that high levels of plasma PON1 provided excellent protection against cholinesterase inhibition in the brain and diaphragm. High PON1 levels are protective against exposure to CPO (14 mg/kg) AChE Activity (% of control) Protection of Paraoxonase against CPO 100 CPO CPO+CPOase 80 60 40 20 0 Brain Diaphragm Plasma RBC What are the consequences of low PON1 levels? The consequences of low levels of plasma PON1 were examined in genetically modified mice that were devoid of liver and plasma PON1. Drs. Shih and Lusis (UCLA) generated mice devoid of PON1. Mice with only one copy of the PON1 gene have ~50% of the PON1 activity levels (paraoxonase, diazoxonase and chlorpyrifos oxonase). These mice have proven to be invaluable in understanding the physiological role of PON1 in detoxifying specific OP compounds as well as the role of PON1 in protecting against vascular disease. (Shih DM, Gu L, Xia Y-R, Navab M, Li W-F, Hama S, Castellani LW, Furlong CE, Costa LG, Fogelman AM, Lusis AJ. 1998. Mice lacking serum paraoxonase are also susceptible to organophosphate toxicity and atherosclerosis. Nature 394:284-287) +/-, and PON1-/- mice PON1 activity levels in PON1+/+ , PON1 +/+/+ -/- PON1 Activity Levels in PON1 , PON1 , and PON1 Mice Liver Liver Serum P a r a o x o n a se P a r a o x o n a se Activity (nm ol/m in/g) Activity (units /lite r ) 350 300 250 200 150 100 50 0 P O N1 +/+ P O N1 +/- 700 600 500 400 300 200 100 0 P O N1 +/+ P O N1 - /- D i a z o x o n a se P O N1 +/- P O N1 - /- D i a z o x o n a se Activity (nm ol/m in/g) Activity (units /lite r ) 5000 4000 3000 2000 1000 0 P O N1 +/+ P O N1 +/- 8000 6000 4000 2000 0 P O N1 - /- P O N1 +/+ C h l o r p y r i fo s-o x o n a se P O N1 - /- C h l o r p y r i fo s-o x o n a se 3000 8000 Activity (nm ol/m in/g) Activity (units /lite r ) P O N1 +/- 2500 2000 1500 1000 500 0 P O N1 +/+ P O N1 +/- P O N1 - /- 6000 4000 2000 0 P O N1 +/+ P O N1 +/- P O N1 - /- W-F Li, Dissertation, University of Washington Role of PON1 in Modulating OP Exposures The dose response curves for the PON1 deficient mice are dramatically changed for dermal exposure to diazoxon (next slide) but much less so to exposure to the parent compound diazinon. PON1-/- mice lacking both PON1 genes were killed by dermal exposures (4 mg/kg) that had no measurable inhibition of brain cholinesterase in normal mice as well as by half that dose. Mice exposed to one-fourth the dose (1 mg/kg) of diazoxon exhibited significant signs of OP intoxication. On the other hand, the differences in sensitivity to the parent compound diazinon were less dramatic (following slide). These observations took us back to one of our earlier papers that included a literature survey of the levels of oxon in residues (Yuknavage et al. 1997, slide after next) and re-emphasized the importance of the PON1 genetic variability in modulating exposure to the oxon component as well as a role in detoxifying the parent compound. (Li W.-F., L.G. Costa, R.J. Richter, T. Hagen, D.M. Shih, A. Tward, A.J. Lusis and C.E. Furlong. 2000. Catalytic efficiency determines the in vivo efficacy of PON1 for detoxifying organophosphates. Pharmacogenetics 10:767-780.) Diazoxon is more toxic to PON1-/- than to PON1+/+ or PON1+/mice A Brain AChE Activity (Units/g) 15 10 PON1 +/+ 5 PON1 +/- *** PON1 -/- *** *** 0 0 1 2 3 4 5 Diazoxon (mg/kg) Li et al. 2000. Pharmacogenetics 10:767-780 Diazinon Toxicity in PON1+/+ & -/- Mice A Brain AChE Activity (units/g) 16 PON1 +/+ 14 PON1 +/- 12 PON1 -/- 10 ** 8 6 4 2 0 0 5 B 10 Diazinon (mg/kg) 15 20 Diaphragm AChE Activity (units/g) 4 PON1 +/+ PON1 +/- 3 PON1 -/- 2 1 ** * 0 0 5 10 15 Diazinon (mg/kg) Li et al. Pharmacogenetics 10:767-780. 20 As noted above, and as seen in the following repeat slide, actual exposures may contain very significant levels of oxon residues. In the study by Ralls et al., the oxon content of the diazinon residues represented 17% of the total residue. (Ralls, J. W., Gilmore, D. R., and Cortes, A. 1966. Fate of radioactive O,O-diethyl O-(2-iso-propyl-4-methylpyridmidin-6-yl) phosphorothioate on field-grown experimental crops. J. Agric. Food Chem. 14:387–392. Literature Survey of Oxon Values in Leaf Foliar Residues Table 1 Oxon levels in total pesticide residues taken from dislodgeable leaf foliar residue and dermal exposure studies Pesticide (units) Ralls et al. (1966) Diazinon (ppmd) Kansoug and Hopkins (1968) Diazinonb Wolfe et al. (1975) Parathion (ng/cm2)d Kraus et al. (1977) Azinphosmethyl (%)d Nigg et al. (1977) Ethion (ng/cm2)d Spear et al. (1977a) Parathion (ng/cm2)d Parathion (mg)e Spear et al. (1977b) Parathion (ng/cm2)d Maddy and Meinders (1987) Azinphosmethyl (mg)e Costello et al. (1989) Malathion (mg)e Schneider et al. (1990) Azinphosmethyl (ng/cm2)d Azinphosmethyl (mg)e Spencer et al. (1991) Azinphosmethyl (%)d McCurdy et al. (1994) Azinphosmethylb Oxona 0.05 NDc 8 0.05 42 84 145 229 ND 659 0.008 272 15 - Thioate 0.25 106 99.95 285 29 39 8 2301 0.31 1450 85 - Total OP 0.3 114 100 327 113 184 237 2960 0.32 1722 100 - Oxon (%) 17 ND 7 0.05 13 74 79 97 ND 22 2.5 16 15 2.3 a Based on the highest value reported in study. Units or values not given in study. c ND, none detected. d Foliar residue measurement. e Dermal monitoring measurement. b Yuknavage et al., J. Toxicol. Environ. Health 1997; 51:35-55 The Importance of the Mouse Genetic Model The next slide shows the most surprising result from the series of dermal exposure experiments with the PON1 knockout mice. It was assumed for nearly 50 years that high levels of PON1 would protect against paraoxon toxicity and conversely, low PON1 levels would render individuals sensitive to this OP. As seen in the next slide, we observed no significant differences in paraoxon sensitivity between wild type mice, PON1 hemizygous mice and PON1 knockout mice. The reason for this will become clear in the slide after next. (Li et al., 2000. Pharmacogenetics, 10:767-779). Paraoxon toxicity is not influenced by PON1 status Brain A AChE Activity (units/g) 18 16 PON1+/+ 14 PON1+/PON1-/- 12 10 8 6 4 2 0 0 0.1 0.2 0.3 0.4 Paraoxon (mg/kg) Li et al., Pharmacogenetics 2000 0.5 0.6 Catalytic Efficiency, the Key to Understanding the Ability of PON1 to Protect Against OP Exposure The next slide provides an explanation for the results seen when the PON1 deficient mice are injected with either purified human PON1-192 alloform (PON1-Q192 or PON1R192) or saline and exposed dermally to the indicated organophosphates (chlorpyrifos oxon, diazoxon and paraoxon). PON1-192 alloforms (Q102 or R192) were purified from human plasma from PON1 Status-typed individual human plasma samples. The purified PON1 was injected into the PON1 deficient mice to determine the effectiveness of each alloform to protect against exposure to chlorpyrifos oxon, diazoxon and paraoxon. The degree of protection provided by each alloform was closely related to the catalytic efficiency of the specific alloform for the given OP. PON1-R192 provided better protection against chlorpyrifos oxon exposure, both alloforms protected nearly equally as well against diazoxon exposure with PON1-R192 protecting a bit better and neither protected against paraoxon exposure, in agreement of a lack of increased sensitivity of PON1 null mice to paraoxon exposure. Thus resistance to diazoxon exposure should be governed primarily by an individual’s plasma PON1 levels, whereas resistance to chlorpyrifos oxon exposure depends on plasma PON1 levels as well as position PON1-192 genotype with PON1-R192 providing the best protection. Li W.-F., L.G. Costa, R.J. Richter, T. Hagen, D.M. Shih, A. Tward, A.J. Lusis and C.E. Furlong. 2000. Catalytic efficiency determines the in vivo efficacy of PON1 for detoxifying organophosphates. Pharmacogenetics 10:767-780.) Catalytic efficiency determines the in vivo efficacy of PON1 for detoxifying organophosphates Catalytic efficiencies of PON1 192Q and PON1 192R enzymes Protection afforded PON1-/- mice by injecting human PON1 192Q orPON1 192R enzymes Chlorpyrifos-oxon Hydrolysis PON1Q192 PON1R192 Km (mM) 0.54 0.25 Vmax (units/mg) 82 64 Vmax/Km 152 256 Diazoxon Hydrolysis CPO Exposure DZO Exposure PON1Q192 PON1R192 Km (mM) 2.98 1.02 Vmax (units/mg) 222 79 Vmax/Km 75 77 Paraoxon Hydrolysis PON1Q192 PON1R192 Km (mM) 0.81 0.52 Vmax (units/mg) 0.57 3.26 Vmax/Km 0.71 6.27 Li et al. 2000. Pharmacogenetics 10:767-780 PO Exposure Further Development of the Mouse Genetic Model Further insights into the ability of PON1 to protect against exposure to chlorpyrifos oxon were obtained from studies with “PON1 humanized mice”. These mice were generated by Dr. Diana Shih and collaborators at UCLA. Essentially, these mice have their mouse PON1 replaced with human PON1-R192 or PON1-Q192. From the original “founder mice”, animals that expressed the same levels of each PON1-192 alloform were chosen for establishing colonies. By choosing animals producing the same levels of each alloform in their plasma, the efficacy in protecting against OP exposure could be tested at any time without having to inject purified human paraoxonase, i.e. they were designed genetically to produce their own human PON1s in the absence of mouse PON1. The next slide shows that the animals expressing human PON1-R192 were much more resistant to cholinesterase inhibition by chlorpyrifos oxon exposure than PON1 deficient animals with PON1-Q192 expressing animals demonstrating intermediate sensitivity except at high doses, where the PON1-Q191 mice were essentially as sensitive as the PON1 deficient mice. This is a very significant observation, since ~50% of individuals of Northern European origin are homozygous for PON1-Q192. [Cole TB, Walter BJ, Shih DM, Tward AD, Lusis AJ, Timchalk C, Richter RJ, Costa LG, Furlong CE. 2005. Toxicity of chlorpyrifos and chlorpyrifos oxon in a transgenic mouse model of the human paraoxonase (PON1) Q192R polymorphism. Pharmacogenet and Genomics 15:589-598]. Dose Response for Chlorpyrifos Oxon Exposure of 21d PON1 Humanized Mice (Q192;R192) Compared with PON1 Null Mice Important since approximately 50% of many populations are homozygous for PON1Q192 What about Mixed Exposures? Experiments were designed to examine interactions between insecticides. Specific organophosphate compounds such as chlorpyrifos oxon, diazoxon and tricresyl phosphate are irreversible inhibitors of carboxylesterase, which is important in the detoxication of malathion and pyretyroids. PhO O PhO H C H C CCl2 C OH H2 CH2 OC carboxylesterase Phenoxybenzyl alcohol S (EtO)2PO N Cl O (O) microsomal (EtO)2PO oxidation Cl Chlorpyrifos Cl N Cl Cl x + plasma HO paraoxonase Chlorpyrifos oxon N (EtO)2PO2- Cl TCP Diethyl phosphate O S S P Dichlorovinyl acid Cl (H2O) O MeO CH3 H3 C Permethrin Cl HOOC CH3 H3 C Cl + CCl2 carboxylesterase OCH2 CH3 S MeO P OH S OH OCH2 CH3 + 2 CH3-CH2-OH OMe OMe O Malathion O MCA Ethanol Conclusion: Prior exposure to chlorpyrifos oxon potentiates sensitivity to malaoxon Other Advantages of the PON1-/Mice PON1 has such a significant impact on the detoxication of the oxons of diazinon and chlorpyrifos that it is difficult to examine the contributions of other enzymes and pathways to the detoxication of these compounds. It will be much easier to examine the contributions of these other enzymes and pathways in the PON1 deficient mice. Detoxication of OPs in PON1 knockouts WT mice S O P450s PON1 ROPOEt OEt ROPOEt OEt P450s AChE O - ROH + OPOEt OEt BChE Inactivated Enzymes Cbx Other Detoxication Products GSH-Xferases ? Conjugates Other targets? PON1-/- mice allow for determining the contributions of other pathways to detoxication and metabolism Summary of Observations Bearing on Exposures to Diazinon/Diazoxon (DZS/DZO) and Chlorpyrifos/ Chlorpyrifos Oxon (CPS/CPO). There are significant genetic and developmental differences in individual sensitivities to OP exposure. Newborns have low PON1 levels which contribute to their increased sensitivity to exposure. Within populations of adults, there is significant variability in PON1 levels (~15 fold) which based on animal model studies, indicate a significant variability in sensitivity to OP exposure. The genetic and developmental variability of PON1 are primarily reflected in sensitivity to the oxon contents of the exposure that have not been considered in product safety studies. Sensitivity to CPS/CPO exposures is governed not only by variability in PON1 levels but also by the PON1-192 Q/R polymorphism with the PON1-R192 alloform protecting better than the PON1-Q192 alloform against exposure. Catalytic efficiency of hydrolysis (oxon inactivation) is the key for determining whether PON1 can protect against a given OP compound. Exposure to the parent compounds can inhibit cytochrome P450 3A4, an enzyme that is very important in hormone metabolism. The Bottom Line A lot of things can happen between the gene encoding PON1 and the final PON1 protein product in the plasma. The high throughput two substrate assay provides the determination of the end result of all of the processes from transcription to the HDL particle and is the method of choice for studies of genetic variation of PON1. 1 60 0 0 D iazoxonase (Units/liter) Functional twosubstrate analysis 1 20 0 0 QQ 80 0 0 QR RR 40 0 0 0 0 5 00 10 0 0 1 5 00 2 00 0 25 00 3 00 0 P a ra o xo n a s e (U n i ts /lite r) PON1 -108CT -162GA P90L (low activity) L55M 124 missplice (low activity) Q192R W194X (premature stop) Research Needs • More Data are needed on oxon content of residues (completely ignored in safety testing) • Data are needed on residue ratios (DZO/DZS) and persistence over time and along product line (wool processing) • Development of realistic (DZO/DZS) exposure models including genetic variability - iterate humanized mouse data with PBPK/PD models • Data are needed on DZO/DZS effects on developing fetus • Identify longer-term biomarkers of exposure • Better endpoints of exposure than ChE inhibition (microarray analysis of effects on gene expression in different tissues/organs) • Effects of DZS exposure on reproductive health • Identification of other targets of DZS/DZO I hope that this presentation has been useful for you. Additional publications from our research laboratory are listed at the end of this presentation. There are plans to generate a paraoxonase resource web site that will provide many more references to earlier research and work done in other laboratories. When this site becomes available, a link will be provided. The next slide lists our many collaborators who have helped explore the different facets of PON1 genetic variability. The following slides include additional references to our studies on organophosphates. If you need to contact me for further information or suggestions for additional research questions, my email address is [email protected] and phone is 206-543-1193. My mailing address is: CE Furlong, Div. Medical Genetics, Box 357720, University of Washington, Seattle, WA 98195-7720. PON1 collaborators •Genomics University of Washington • Toxicology studies LG Costa W-F Li TB Cole • Genetics, purification & expression RJ Richter R Jampsa T Hagen VH Brophy • • • Pathology studies CP Brewer Mouse behavior studies TB Cole J Fisher B Walter T Burbacher D Nickerson C Carlson M Rieder Parkinson’s Studies Harvey Checkoway Paola Costa-Mallen Fred Farin Samir Kelada Gary Franklin •Cardiovascular studies G Jarvik UCLA • Pon1-/- and transgenic mice AJ Lusis DM Shih A Tward UC Berkeley PNNL, Batelle • PBPK/PD Modeling C Timchalk Mother/Infant Study B Eskenazi N Holland A Bradman NIEHS grants and contracts Development/Toxico-genomics TB Cole, H Zarbl, R Bumgarner J Furlong, M Katze G Geiss ES09883, ES04696, P30 ES07033, ES09601/EPA-R826886, U19 ES11387 P42ES04696 References from our laboratory • • • • • • • • • • • • • • • • • • • • • Mueller, R. F., Hornung, S., Furlong, C. E., Anderson, J., Giblett, E. R. and Motulsky, A. G. 1983. Plasma paraoxonase polymorphism: a new enzyme assay, population, family, biochemical and linkage studies. Am. J. Hum. Genet. 35:393-408. Ortigoza-Ferado, J., Richter, R., Hornung, S. K., Motulsky, A. G. and Furlong, C. E. 1984. Paraoxon hydrolysis in human serum mediated by a genetically variable arylesterase and albumin. Am. J. Hum. Genet. 36:295-305. Furlong, C. E., Richter, R. J., Seidel, S. L. and Motulsky, A. G. 1988. Role of genetic polymorphism of human plasma paraoxonase/arylesterase in hydrolysis of the insecticide metabolites chlorpyrifos oxon and paraoxon. Am. J. Hum. Genet. 43: 230-238. Furlong, C.E., R.J. Richter, S.L. Seidel, L.G. Costa and A.G. Motulsky. Spectrophotometric assays for the enzymatic hydrolysis of the active metabolites of chlorpyrifos and parathion by plasma paraoxonase/arylesterase. 1989. Anal. Biochem. 180:242-247. Costa, L.G., B.E. McDonald, S.D. Murphy, G.S. Omenn, R.J. Richter, A.G. Motulsky and C.E. Furlong. 1990. Serum paraoxonase and its influence on paraoxon and chlorpyrifos-oxon toxicity in rats. Toxicol. Appl. Pharmacol. 103:66-76. Furlong, C.E., Richter, R.J., Chapline, C. and Crabb, J.W. 1991. Purification of rabbit and human serum paraoxonase. Biochemistry 30:1013310140. Hassett, C., Richter, R.J. Humbert, R., Chapline, C., Crabb, J.W., Omiecinski, C.J. and Furlong, C.E. 1991. Characterization of cDNA clones encoding rabbit and human serum paraoxonase: the mature protein retains its signal sequence. Biochemistry 30:10141-10149. Humbert, R., D.A. Adler, C.M. Disteche, C. Hassett, C.J. Omiecinski and C.E. Furlong. 1993. The molecular basis of the human serum paraoxonase activity polymorphism. Nature Genetics 3:73-76. Li, W.-F., L.G. Costa, and C.E. Furlong, 1993. Serum paraoxonase status: a major factor in determining resistance to organophosphates. J. Toxicol. Environ. Health. 40:337-346. Li, W.-F., C. E. Furlong and L.G. Costa.. 1995. Paraoxonase protects against chlorpyrifos toxicity in mice. Toxicol. Lett 76:219-226. Clendenning, J.B., R. Humbert, E.D. Green, C.Wood, D. Traver and C.E. Furlong. 1996. Structural organization of the human PON1 gene. Genomics 35:586-589. Nevin, D.N., A. Zambon, C.E. Furlong, R.J. Richter, R. Humbert and J.D. Brunzell. Paraoxonase genotypes, lipoprotein lipase activity and high density lipoproteins. 1996. Arterioscler. Thromb. Vasc. Biol. 16:1243-1249. Yuknavage, K.L., R.A. Fenske, D.A. Kalman, M. C. Keifer, C.E. Furlong. 1997. Simulated dermal contamination with capillary samples and field cholinesterase biomonitoring. J. Toxicol. and Env. Health 51:35-55. Li, W.-F., L.G. Costa and C.E. Furlong. 1997. Paraoxonase (Pon1) gene in mice: sequencing, chromosomal location, and developmental expression. Pharmacogenetics 7:137-144. Shih DM, Gu L, Xia Y-R, Navab M, Li W-F, Hama S, Castellani LW, Furlong CE, Costa LG, Fogelman AM, Lusis AJ. 1998. Mice lacking serum paraoxonase are susceptible to organophosphate toxicity and atherosclerosis. Nature 394:284-287. Richter, RJ and Furlong, CE. 1999. Determination of paraoxonase (PON1) status requires more than genotyping. Pharmacogenetics 9:745-753. Brophy, V.H., G.P. Jarvik, R.J. Richter, L.S. Rozek, G.D. Schellenberg and C.E. Furlong. 2000. Analysis of paraoxonase (PON1) L55M status requires both genotype and phenotype. Pharmacogenetics 10:453-460. Jarvik, G.P., L.S. Rozek, V.H. Brophy, T.S. Hatsukami, R.J. Richter, G.D. Schellenberg, C.E. Furlong. 2000. Paraoxonase phenotype is a better predictor of vascular disease than PON1192 or PON155 genotpye. Atheroscler. Thromb. Vasc. Biol. 20:2442-2447. Li W.-F., L.G. Costa, R.J. Richter, T. Hagen, D.M. Shih, A. Tward, A.J. Lusis and C.E. Furlong. 2000. Catalytic efficiency determines the in vivo efficacy of PON1 for detoxifying organophosphates. Pharmacogenetics 10:767-780. Brophy, V.H., M.D. Hastings, J.B. Clendennning, R.J. Richter, G.P. Jarvik and C.E. Furlong. 2001. Polymorphisms in the human paraoxonase (PON1) promoter. Pharmacogenetics 11:77-84. Brophy, V.H., R.L. Jampsa, J.B. Clendenning, L.A. McKinstry, G.P. Jarvik and C.E. Furlong. 2001. Effects of 5' regulatory region polymorphisms on paraoxonase (PON1) expression. Am J Hum Genet 68:1428-1436. References from our laboratory, continued Furlong, C.E., T.B. Cole, G.P. Jarvik, L.G. Costa. 2002. Pharmacogenomic considerations of the paraoxonase polymorphisms. Pharmacogenomics 3(3):341-8. Jarvik GP, Tsai NT, McKinstry LA Wani R, Brophy VH, Richter RJ., Schellenberg GD, Heagerty PJ, Hatsukami TS, Furlong CE. 2002. Vitamin C and E intake are associated with increased PON1 activity. Atheroscler. Thromb. Vasc. Biol. 22(8):1329-33. Jarvik GP, R Jampsa, RJ Richter, C Carlson, M Rieder, D Nickerson and CE Furlong. 2003. Novel Paraoxonase (PON1) nonsense and missense mutations predicted by functional genomic assay of PON1 status. Pharmacogenetics 13:291-295. Jarvik GP, Hatsukami TS, Carlson CS, Richter RJ, Jampsa R, Brophy VH, Margolin S, Rieder MJ, Nickerson DA, Schellenberg GD, Heagerty PJ, Furlong CE. 2003. Paraoxonase activity, but not haplotype utilizing the linkage disequilibrium structure, predicts vascular disease. Arterioscler Thromb Vasc Biol 23:1465-1471. Cole TB, RL Jampsa, BJ Walter, TL Arndt, RJ Richter, DM Shih, A Tward, AJ Lusis, RM Jack, LG Costa, and CE Furlong. 2003. Expression of human paraoxonase (PON1) during development. Pharmacogenetics 13:357-364. Kelada SN, P Costa-Mallen, H Checkoway, CE Furlong, GP. Jarvik, HA Viernes, FM Farin, T Smith-Weller, GM. Franklin, WT Longstreth Jr., PD. Swanson, and LG Costa. 2003. Paraoxonase 1 promoter and coding region polymorphisms in Parkinson’s disease. J Neurol Neurosurg Psychiatry 74:546-547. B. Eskenazi, K. Harley, A. Bradman, E. Weltzien, N. Jewell, D. Barr, C. Furlong, and N. Holland. 2004. Association of in utero Organophosphate Pesticide Exposure and Fetal Growth and Length of Gestation in an Agricultural Populations. Environ Health Perspect 112:1116-1124 RJ Richer, RL Jampsa, GP Jarvik, LG Costa and CE Furlong. Determination of paraoxonase 1 (PON1) status and genotypes at specific polymorphic sites. Current Protocols in Toxicology, MD Mains, LG Costa, DJ Reed, E Hodgson, eds. John Wiley and Sons, NY, NY. 2004: 4.12.1-4.12.19. Rozek LS, Hatsukami TS,. Richter RJ, Ranchalis J, Nakayama K, McKinstry LA, Gortner DA, Boyko, E, Schellenberg GD, Furlong CE, Jarvik GP. 2005. The correlation of paraoxonase (PON1) activity with lipid and lipoprotein levels differs with vascular disease status. J Lipid Res 46:1888-1895. Furlong, C.E., T.B. Cole, G.P. Jarvik, L.G. Costa. 2002. Pharmacogenomic considerations of the paraoxonase polymorphisms. Pharmacogenomics 3(3):341-8. Jarvik GP, Tsai NT, McKinstry LA Wani R, Brophy VH, Richter RJ., Schellenberg GD, Heagerty PJ, Hatsukami TS, Furlong CE. 2002. Vitamin C and E intake are associated with increased PON1 activity. Atheroscler. Thromb. Vasc. Biol. 22(8):1329-33. Jarvik GP, R Jampsa, RJ Richter, C Carlson, M Rieder, D Nickerson and CE Furlong. 2003. Novel Paraoxonase (PON1) nonsense and missense mutations predicted by functional genomic assay of PON1 status. Pharmacogenetics 13:291-295. Jarvik GP, Hatsukami TS, Carlson CS, Richter RJ, Jampsa R, Brophy VH, Margolin S, Rieder MJ, Nickerson DA, Schellenberg GD, Heagerty PJ, Furlong CE. 2003. Paraoxonase activity, but not haplotype utilizing the linkage disequilibrium structure, predicts vascular disease. Arterioscler Thromb Vasc Biol 23:1465-1471. Cole TB, RL Jampsa, BJ Walter, TL Arndt, RJ Richter, DM Shih, A Tward, AJ Lusis, RM Jack, LG Costa, and CE Furlong. 2003. Expression of human paraoxonase (PON1) during development. Pharmacogenetics 13:357-364. Kelada SN, P Costa-Mallen, H Checkoway, CE Furlong, GP. Jarvik, HA Viernes, FM Farin, T Smith-Weller, GM. Franklin, WT Longstreth Jr., PD. Swanson, and LG Costa. 2003. Paraoxonase 1 promoter and coding region polymorphisms in Parkinson’s disease. J Neurol Neurosurg Psychiatry 74:546-547. B. Eskenazi, K. Harley, A. Bradman, E. Weltzien, N. Jewell, D. Barr, C. Furlong, and N. Holland. 2004. Association of in utero Organophosphate Pesticide Exposure and Fetal Growth and Length of Gestation in an Agricultural Populations. Environ Health Perspect 112:1116-1124 RJ Richer, RL Jampsa, GP Jarvik, LG Costa and CE Furlong. Determination of paraoxonase 1 (PON1) status and genotypes at specific polymorphic sites. Current Protocols in Toxicology, MD Mains, LG Costa, DJ Reed, E Hodgson, eds. John Wiley and Sons, NY, NY. 2004: 4.12.1-4.12.19 References from our laboratory, continued . . Rozek LS, Hatsukami TS,. Richter RJ, Ranchalis J, Nakayama K, McKinstry LA, Gortner DA, Boyko, E, Schellenberg GD, Furlong CE, Jarvik GP. 2005. The correlation of paraoxonase (PON1) activity with lipid and lipoprotein levels differs with vascular disease status. J Lipid Res 46:1888-1895. Cole TB, Walter BJ, Shih DM, Tward AD, Lusis AJ, Timchalk C, Richter RJ, Costa LG, Furlong CE. 2005. Toxicity of chlorpyrifos and chlorpyrifos oxon in a transgenic mouse model of the human paraoxonase (PON1) Q192R polymorphism. In press, Pharmacogenet and Genomics 15:589-598. Costa, L.G., W.F. Li, R. J. Richter, D. M. Shih, A. Lusis, and, C.E. Furlong. 1999. The role of paraoxonase (PON1) in the detoxication of organophosphates and its human polymorhism. Chem-Biol Interactions 119-120:429-438. La Du BN, Furlong CE and Reiner E. 1999. Recommended nomenclature system for the paraoxonases. Chem-Biol Interactions 119-120:599-601. Furlong CE, Li W-F, Richter RJ, Shih DM, Lusis AJ, Alleva E and Costa LG. 2000. Genetic and temporal determinants of pesticide sensitivity: role of paraoxonase (PON1). NeuroToxicol. 21(1-2):91-100. Furlong, CE, Li, W-F, Brophy, VH, Jarvik, GP, Richter, RJ, Shih, DM, Lusis, AJ, Costa, LG. 2000. The PON1 gene and detoxication. NeuroToxicol. 21:581-588. Furlong, C., W-F Li, , DM Shih, AJ Lusis, RJ Richter, and LG Costa. 2002. Genetic factors in susceptibility: serum PON1 variation between individuals and species. Hum and Ecol Risk Assess 8:31-43. AWARDED PAPER OF THE YEAR AWARD BY THE JOURNAL EDITORS Young JG, Eskenazi B, Gladstone EA, Bradman A, Pedersen L, Johnson C, Barr DB, Furlong CE, Holland NT. 2005. Association between in utero organophosphate pesticide exposure and neurobehavioral functioning in neonates. Neurotoxicology 26(2):199-209. Furlong CE, ColeTB, Jarvik GP, Pettan-Brewer C, Geiss GK, Rebecca J. Richter RJ, Diana M. Shih DM, Tward AJ, Lusis AJ, Costa LG. 2005. Role of paraoxonase (PON1) status in pesticide sensitivity: genetic and temporal determinants. Neurotoxicology 26:26:651-659 L.G. Costa, C.E. Furlong. 2002. Paraoxonase (PON1) in Health and Disease: Basic and Clinical Aspects. L.G. Costa and C.E. Furlong, eds. Kluwer Academic Press. Boston. Costa, L. G., Richter, R. J., Murphy, S. D., Omenn, G. S., Motulsky, A. G. and Furlong, C. E. Species Differences in Serum Paraoxonase Activity Correlate with Sensitivity to Paraoxon Toxicity. In: Nato ASI Series, Vol. H13. "Toxicology of Pesticides: Experimental, Clinical and Regulatory Aspects." pp. 263266. L. G. Costa, et al., eds. Springer-Verlag, Berlin, Heidelberg 1987 Costa L.G., R.J. Richter, W.-F. Li, T. Cole, M. Guizzetti, C.E. Furlong. 2003. Paraoxonase (PON1) as a biomarker of susceptibility for organophosphate toxicity. Biomarkers. 8(1):1-12. Costa LG, Cole TB, Jarvik GP, Furlong CE. 2003. Functional Genomics of the Paraoxonase (PON1) Polymorphisms: Effects on Pesticide Sensitivity, Cardiovascular Disease, and Drug Metabolism. Ann Rev Med 54:371-392. Costa LG, TB Cole and CE Furlong. 2003. Polymorphisms of paraoxonase (PON1) and their significance in clinical toxicology of organophosphates. J Toxicol Clin Toxicol 41:37-45. Battuelo K, Furlong C, Fenske R, Austin M, Burke W. Paraoxonase polymorphisms and susceptibility of organophosphate pesticides. 2004. In, Human Genome Epidemiology: Scientific Foundations for Using Genetic Information to Improve Health and Prevent Disease. Eds. MJ Khoury, J Little, W Burke. Oxford Univ. Press. NY. Furlong, CE, W-F Li, TB Cole, R Jampsa, RJ Richter, GP Jarvik, DM Shih, A Tward, AJ Lusis, LG Costa. Understanding the significance of genetic variability in the human PON1 gene. Toxicogenomics and Proteomics. JJ Valdez and JW Sekowski eds. IOS Press, Washington, DC. 2004. Costa LG, Cole TB, Vitalone A and Furlong CE. 2005. Measurement of paraoxonase (PON1) status: a biomarker of susceptibility to organophosphate toxicity. Clin Chim Acta 352:37-47. . References from our laboratory, continued . Costa LG, Vitalone A, Cole TB and Furlong CE. 2005. Modulation of paraoxonase (PON1) activity. Biochemical Pharmacology 69(4):541-550. Furlong CE, Cole TB, Walter BJ, Shih DM, Tward A, Lusis AJ, Timchalk C, Richter RJ, Costa LG. Paraoxonase 1 (PON1) status and risk of insecticide exposure. 2005 J Biochem Toxicol 19:182-183. Costa LG and CE Furlong. Paraoxonase (PON1) gene polymorphisms. Encyclopedia Of Medical Genomics and Proteomics 2005; pp 965-969. DOI: 10.1081/E-EDGP-120030804 Costa LG, Cole TB, Furlong CE. 2005. Paraoxonase (PON1): from toxicology to cardiovascular medicine. Acta Biomed Suppl 2; 50-57. C.E. Furlong. 2000. PON1 Status and neurologic symptom complexes in Gulf War veterans. Genome Research 10:153-155. Costa LG, Cole TB, Vitalone A, Furlong CE. Paraoxonase (PON1) polymorphisms and toxicity of organophosphates. In: Toxicology of Organophosphates and Carbamate Pesticides. RC Gupta, ed. Elsevier Inc., San Diego, 2005. In press. Furlong C, Holland N, Richter R, Bradman A, Ho A, and B Eskenazi. PON1 status of farmworker mothers and children as a predictor of organophosphate sensitivity. In press: Pharmacogenetics and Genomics.